// SPDX-License-Identifier: EPL-2.0 OR GPL-2.0-or-later
// SPDX-FileCopyrightText: Bradley M. Bell <bradbell@seanet.com>
// SPDX-FileContributor: 2003-22 Bradley M. Bell
// ----------------------------------------------------------------------------

/*
{xrst_begin rc_sparsity.cpp}

Preferred Sparsity Patterns: Row and Column Indices: Example and Test
#####################################################################

Purpose
*******
This example show how to use row and column index sparsity patterns
:ref:`sparse_rc-name` to compute sparse Jacobians and Hessians.
This became the preferred way to represent sparsity on
:ref:`2017-02-09<2017@mm-dd@02-09>` .

{xrst_literal
   // BEGIN C++
   // END C++
}

{xrst_end rc_sparsity.cpp}
*/
// BEGIN C++
# include <cppad/cppad.hpp>
namespace {
   using CppAD::sparse_rc;
   using CppAD::sparse_rcv;
   using CppAD::NearEqual;
   //
   typedef CPPAD_TESTVECTOR(bool)                b_vector;
   typedef CPPAD_TESTVECTOR(size_t)              s_vector;
   typedef CPPAD_TESTVECTOR(double)              d_vector;
   typedef CPPAD_TESTVECTOR( CppAD::AD<double> ) a_vector;
   //
   double eps99 = 99.0 * std::numeric_limits<double>::epsilon();
   // -----------------------------------------------------------------------
   // function f(x) that we are computing sparse results for
   // -----------------------------------------------------------------------
   a_vector fun(const a_vector& x)
   {  size_t n  = x.size();
      a_vector ret(n + 1);
      for(size_t i = 0; i < n; i++)
      {  size_t j = (i + 1) % n;
         ret[i]     = x[i] * x[i] * x[j];
      }
      ret[n] = 0.0;
      return ret;
   }
   // -----------------------------------------------------------------------
   // Jacobian
   // -----------------------------------------------------------------------
   bool check_jac(
      const d_vector&                       x      ,
      const sparse_rcv<s_vector, d_vector>& subset )
   {  bool ok  = true;
      size_t n = x.size();
      //
      ok &= subset.nnz() == 2 * n;
      const s_vector& row( subset.row() );
      const s_vector& col( subset.col() );
      const d_vector& val( subset.val() );
      s_vector row_major = subset.row_major();
      for(size_t i = 0; i < n; i++)
      {  size_t j = (i + 1) % n;
         size_t k = 2 * i;
         //
         ok &= row[ row_major[k] ]   == i;
         ok &= row[ row_major[k+1] ] == i;
         //
         size_t ck  = col[ row_major[k] ];
         size_t ckp = col[ row_major[k+1] ];
         double vk  = val[ row_major[k] ];
         double vkp = val[ row_major[k+1] ];
         //
         // put diagonal element first
         if( j < i )
         {  std::swap(ck, ckp);
            std::swap(vk, vkp);
         }
         // diagonal element
         ok &= ck == i;
         ok &= NearEqual( vk, 2.0 * x[i] * x[j], eps99, eps99 );
         // off diagonal element
         ok &= ckp == j;
         ok &= NearEqual( vkp, x[i] * x[i], eps99, eps99 );
      }
      return ok;
   }
   // Use forward mode for Jacobian and sparsity pattern
   bool forward_jac(CppAD::ADFun<double>& f)
   {  bool ok = true;
      size_t n = f.Domain();
      //
      // sparsity pattern for identity matrix
      sparse_rc<s_vector> pattern_in(n, n, n);
      for(size_t k = 0; k < n; k++)
         pattern_in.set(k, k, k);
      //
      // sparsity pattern for Jacobian
      bool transpose     = false;
      bool dependency    = false;
      bool internal_bool = false;
      sparse_rc<s_vector> pattern_out;
      f.for_jac_sparsity(
         pattern_in, transpose, dependency, internal_bool, pattern_out
      );
      //
      // compute entire Jacobian
      size_t                         group_max = 1;
      std::string                    coloring  = "cppad";
      sparse_rcv<s_vector, d_vector> subset( pattern_out );
      CppAD::sparse_jac_work         work;
      d_vector x(n);
      for(size_t j = 0; j < n; j++)
         x[j] = double(j + 2);
      size_t n_sweep = f.sparse_jac_for(
         group_max, x, subset, pattern_out, coloring, work
      );
      //
      // check Jacobian
      ok &= check_jac(x, subset);
      ok &= n_sweep == 2;
      //
      return ok;
   }
   // Use reverse mode for Jacobian and sparsity pattern
   bool reverse_jac(CppAD::ADFun<double>& f)
   {  bool ok = true;
      size_t n = f.Domain();
      size_t m = f.Range();
      //
      // sparsity pattern for identity matrix
      sparse_rc<s_vector> pattern_in(m, m, m);
      for(size_t k = 0; k < m; k++)
         pattern_in.set(k, k, k);
      //
      // sparsity pattern for Jacobian
      bool transpose     = false;
      bool dependency    = false;
      bool internal_bool = false;
      sparse_rc<s_vector> pattern_out;
      f.rev_jac_sparsity(
         pattern_in, transpose, dependency, internal_bool, pattern_out
      );
      //
      // compute entire Jacobian
      std::string                    coloring  = "cppad";
      sparse_rcv<s_vector, d_vector> subset( pattern_out );
      CppAD::sparse_jac_work         work;
      d_vector x(n);
      for(size_t j = 0; j < n; j++)
         x[j] = double(j + 2);
      size_t n_sweep = f.sparse_jac_rev(
         x, subset, pattern_out, coloring, work
      );
      //
      // check Jacobian
      ok &= check_jac(x, subset);
      ok &= n_sweep == 2;
      //
      return ok;
   }
   // ------------------------------------------------------------------------
   // Hessian
   // ------------------------------------------------------------------------
   bool check_hes(
      size_t                                i      ,
      const d_vector&                       x      ,
      const sparse_rcv<s_vector, d_vector>& subset )
   {  bool ok  = true;
      size_t n = x.size();
      size_t j = (i + 1) % n;
      //
      ok &= subset.nnz() == 3;
      const s_vector& row( subset.row() );
      const s_vector& col( subset.col() );
      const d_vector& val( subset.val() );
      s_vector row_major = subset.row_major();
      //
      double v0 = val[ row_major[0] ];
      double v1 = val[ row_major[1] ];
      double v2 = val[ row_major[2] ];
      if( j < i )
      {  ok &= row[ row_major[0] ] == j;
         ok &= col[ row_major[0] ] == i;
         ok &= NearEqual( v0, 2.0 * x[i], eps99, eps99 );
         //
         ok &= row[ row_major[1] ] == i;
         ok &= col[ row_major[1] ] == j;
         ok &= NearEqual( v1, 2.0 * x[i], eps99, eps99 );
         //
         ok &= row[ row_major[2] ] == i;
         ok &= col[ row_major[2] ] == i;
         ok &= NearEqual( v2, 2.0 * x[j], eps99, eps99 );
      }
      else
      {  ok &= row[ row_major[0] ] == i;
         ok &= col[ row_major[0] ] == i;
         ok &= NearEqual( v0, 2.0 * x[j], eps99, eps99 );
         //
         ok &= row[ row_major[1] ] == i;
         ok &= col[ row_major[1] ] == j;
         ok &= NearEqual( v1, 2.0 * x[i], eps99, eps99 );
         //
         ok &= row[ row_major[2] ] == j;
         ok &= col[ row_major[2] ] == i;
         ok &= NearEqual( v2, 2.0 * x[i], eps99, eps99 );
      }
      return ok;
   }
   // Use forward mode for Hessian and sparsity pattern
   bool forward_hes(CppAD::ADFun<double>& f)
   {  bool ok = true;
      size_t n = f.Domain();
      size_t m = f.Range();
      //
      b_vector select_domain(n);
      for(size_t j = 0; j < n; j++)
         select_domain[j] = true;
      sparse_rc<s_vector> pattern_out;
      //
      for(size_t i = 0; i < m; i++)
      {  // select i-th component of range
         b_vector select_range(m);
         d_vector w(m);
         for(size_t k = 0; k < m; k++)
         {  select_range[k] = k == i;
            w[k] = 0.0;
            if( k == i )
               w[k] = 1.0;
         }
         //
         bool internal_bool = false;
         f.for_hes_sparsity(
            select_domain, select_range, internal_bool, pattern_out
         );
         //
         // compute Hessian for i-th component function
         std::string                    coloring  = "cppad.symmetric";
         sparse_rcv<s_vector, d_vector> subset( pattern_out );
         CppAD::sparse_hes_work         work;
         d_vector x(n);
         for(size_t j = 0; j < n; j++)
            x[j] = double(j + 2);
         size_t n_sweep = f.sparse_hes(
            x, w, subset, pattern_out, coloring, work
         );
         //
         // check Hessian
         if( i == n )
            ok &= subset.nnz() == 0;
         else
         {  ok &= check_hes(i, x, subset);
            ok &= n_sweep == 1;
         }
      }
      return ok;
   }
   // Use reverse mode for Hessian and sparsity pattern
   bool reverse_hes(CppAD::ADFun<double>& f)
   {  bool ok = true;
      size_t n = f.Domain();
      size_t m = f.Range();
      //
      // n by n identity matrix
      sparse_rc<s_vector> pattern_in(n, n, n);
      for(size_t j = 0; j < n; j++)
         pattern_in.set(j, j, j);
      //
      bool transpose     = false;
      bool dependency    = false;
      bool internal_bool = true;
      sparse_rc<s_vector> pattern_out;
      //
      f.for_jac_sparsity(
         pattern_in, transpose, dependency, internal_bool, pattern_out
      );
      //
      for(size_t i = 0; i < m; i++)
      {  // select i-th component of range
         b_vector select_range(m);
         d_vector w(m);
         for(size_t k = 0; k < m; k++)
         {  select_range[k] = k == i;
            w[k] = 0.0;
            if( k == i )
               w[k] = 1.0;
         }
         //
         f.rev_hes_sparsity(
            select_range, transpose, internal_bool, pattern_out
         );
         //
         // compute Hessian for i-th component function
         std::string                    coloring  = "cppad.symmetric";
         sparse_rcv<s_vector, d_vector> subset( pattern_out );
         CppAD::sparse_hes_work         work;
         d_vector x(n);
         for(size_t j = 0; j < n; j++)
            x[j] = double(j + 2);
         size_t n_sweep = f.sparse_hes(
            x, w, subset, pattern_out, coloring, work
         );
         //
         // check Hessian
         if( i == n )
            ok &= subset.nnz() == 0;
         else
         {  ok &= check_hes(i, x, subset);
            ok &= n_sweep == 1;
         }
      }
      return ok;
   }
}
// driver for all of the cases above
bool rc_sparsity(void)
{  bool ok = true;
   //
   // record the funcion
   size_t n = 20;
   size_t m = n + 1;
   a_vector x(n), y(m);
   for(size_t j = 0; j < n; j++)
      x[j] = CppAD::AD<double>(j+1);
   CppAD::Independent(x);
   y = fun(x);
   CppAD::ADFun<double> f(x, y);
   //
   // run the example / tests
   ok &= forward_jac(f);
   ok &= reverse_jac(f);
   ok &= forward_hes(f);
   ok &= reverse_hes(f);
   //
   return ok;
}
// END C++
